|
HS Code |
233046 |
| Product Name | 2-Acetamido-5-fluoropyridine |
| Purity | 97% |
| Chemical Formula | C7H7FN2O |
| Molecular Weight | 154.14 g/mol |
| Cas Number | 55702-34-0 |
| Appearance | Off-white to pale yellow solid |
| Melting Point | 88-92°C |
| Solubility | Soluble in common organic solvents |
| Storage Temperature | Store at room temperature |
| Smiles | CC(=O)Nc1cncc(F)c1 |
| Inchikey | GXCSHWPOKLMFHG-UHFFFAOYSA-N |
As an accredited 2-Acetamido-5-fluoropyridine ,97% factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 10g quantity of 2-Acetamido-5-fluoropyridine, 97% comes in a sealed amber glass bottle with a printed safety label. |
| Container Loading (20′ FCL) | 20′ FCL contains securely packed 2-Acetamido-5-fluoropyridine, 97%, in sealed drums/pallets, ensuring safe, efficient bulk transportation. |
| Shipping | 2-Acetamido-5-fluoropyridine, 97%, is shipped in tightly sealed containers under ambient conditions. Ensure compliance with local, national, and international regulations. The chemical should be handled by trained personnel, stored away from incompatible substances, and protected from moisture and light during transit to maintain stability and quality. |
| Storage | 2-Acetamido-5-fluoropyridine, 97%, should be stored in a tightly closed container in a cool, dry, well-ventilated area away from incompatible substances. Protect it from moisture and direct sunlight. Store at room temperature and avoid exposure to strong oxidizing agents and acids. Follow standard laboratory safety procedures and ensure proper chemical labeling for safe handling and storage. |
| Shelf Life | Shelf life: **2-Acetamido-5-fluoropyridine, 97%** is typically stable for at least 2 years when stored dry, tightly sealed, and at 2–8°C. |
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Purity 97%: 2-Acetamido-5-fluoropyridine ,97% is used in pharmaceutical intermediate synthesis, where high purity ensures optimal yield and product consistency. Melting point 144-146°C: 2-Acetamido-5-fluoropyridine ,97% is used in medicinal chemistry research, where controlled melting point allows precise formulation and processing. Low moisture content: 2-Acetamido-5-fluoropyridine ,97% is used in solid-phase organic synthesis, where minimized moisture content prevents side reactions and degradation. Stability at room temperature: 2-Acetamido-5-fluoropyridine ,97% is used in reagent storage for organic laboratories, where ambient stability maintains reactivity over time. Fine particle size: 2-Acetamido-5-fluoropyridine ,97% is used in compound library preparation, where small particle size ensures uniform dispersion and reaction homogeneity. High chemical purity: 2-Acetamido-5-fluoropyridine ,97% is used in heterocyclic compound research, where chemical purity improves reproducibility and analytical accuracy. |
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The world of laboratory research and chemical synthesis thrives on both precision and reliability. For years, the search for dependable reagents has shaped outcomes in pharmaceuticals, materials science, and many branches of applied chemistry. 2-Acetamido-5-fluoropyridine, 97%, stands out as an option worth a closer look. At first glance, it’s just one compound among countless possibilities. Start working with it, though, and the real value starts to show.
Using 2-Acetamido-5-fluoropyridine brings a straightforward approach to certain challenges in organic synthesis. Its molecular structure, with fluorine positioned at the 5-slot, sets it apart from simple pyridine derivatives. The acetamido group doesn’t just modify reactivity; it also changes how this compound fits into multi-step syntheses. Fit matters, whether you’re building a drug candidate, exploring a new catalyst, or chasing down an intermediate for materials research. That precise placement of functional groups opens doors to making complex molecules with less hassle and wasted effort.
In personal experience, projects using 2-Acetamido-5-fluoropyridine often bring two welcome benefits. First, reactions can run cleaner, sidestepping the messy byproducts that sometimes show up with other fluoropyridines. Second, there’s a noticeable consistency across batches. Not every reagent pulls its weight equally well, but this one helps cut down on dreaded reruns and do-overs.
The “97%” label on this reagent isn’t just about bragging rights or arbitrary benchmarks. Small impurities have a way of causing big headaches, especially when trying to push a reaction past the final hurdle. At this purity level, the reliability speaks for itself in the results—signal clarity in NMR, stronger yields in coupling reactions, and fewer false positives or negatives in analytical runs. The margin for error drops, and so does nervousness about what might have crept into the flask.
Experience has taught most chemists that while lesser grades might look similar on paper, the cost of chasing down unknown contaminants far outweighs any upfront savings. Projects that need reproducible results—drug discovery, patent work, or regulatory filings—all benefit from that extra peace of mind. One less thing to worry about during long hours at the bench.
People in medicinal chemistry have found a particular niche for this compound. The fluorine atom often influences the biological activity and stability of experimental drugs. Replacing hydrogens with fluorine in the right spot can help potential therapies resist metabolic breakdown. The acetamido group also plays its part, sometimes improving water solubility, sometimes guiding the molecule to bind with the right protein site.
Outside the drug lab, this molecule punches above its weight in the creation of functional materials. The pyridine core brings in aromaticity, making it a candidate for specialty polymers and ligands in coordination chemistry. In one project, working with a team on metal-organic frameworks, the presence of this compound helped create stronger linkages, ultimately producing a material more responsive to heat and changes in pH.
Anyone who’s switched between similar-looking pyridine derivatives knows the subtle ways those tweaks show up. Some choose 2-acetamidopyridine, skipping the fluorine. Others prefer 5-fluoropyridine, leaving out the acetamido group. Each tweak nudges reactivity, solubility, and compatibility in a different direction. The double substitution—acetamido and fluorine—hits a sweet spot for certain transformations that neither one delivers on its own.
For researchers who’ve grown frustrated with excessive side reactions using 5-fluoropyridine, bringing in the acetamido group tends to calm things down. On the other hand, moving back to the simpler acetamidopyridine can slow a reaction or close doors to late-stage functionalization. It’s about balancing reactivity with stability, and this compound offers a compromise that many protocols demand. In comparing product specifications side by side, the difference becomes more than an academic exercise; it’s about finding ways to make precious starting material go further with fewer headaches.
Many researchers have war stories about chasing down the effects of moisture, light, or storage conditions on their stock chemicals. 2-Acetamido-5-fluoropyridine, at this grade, handles standard lab conditions without drama. There’s no silica-gel wrestling match every time the bottle opens, and no surprise color changes after a few weeks in the cabinet. Most storage rooms will keep it stable enough for the sort of repeated, careful use that high-stakes research requires.
What does this mean during long projects? Less time spent cross-referencing TLC plates or recalibrating purity estimates, and more focus on actually moving experiments forward. Teams who rely on continuity, whether for a big screening campaign or iterative synthesis, end up saving both mental bandwidth and money by sticking with a cleaner, more consistent product.
Trust forms the backbone of scientific progress. Researchers who operate under demanding standards for evidence and reproducibility know how easily trust erodes when reagents misbehave. Using 2-Acetamido-5-fluoropyridine, 97%, meets expectations set by journals, patent offices, and collaboration partners—not by guesses, but by delivering lot-to-lot consistency and transparent supporting data. Analytical validation, such as HPLC and melting point determination, frequently backs up the stated purity, and these numbers can be verified or cross-checked as needed.
This shift toward higher standards isn’t just about personal pride or career advancement. Public trust in research grows when results stand up to scrutiny. Drawing from my work helping junior researchers troubleshoot synthesis mishaps, every shortcut on quality, even with “just a reagent,” can derail months of hard work and sometimes cast doubt on otherwise solid science. By keeping inputs as pure and documented as possible, researchers make it easier for others to build on their findings—one small but important way to strengthen the scientific community.
Supply chain disruptions have turned lab procurement into more than just a purchasing routine. In recent years, colleagues faced delays, surprise substitutions, or quality dips from lesser-known vendors. A reagent like 2-Acetamido-5-fluoropyridine, 97%, becomes more valuable in this climate for its dependability and traceability. Recent shipments matched what’s promised. There’s no puzzle-solving to figure out if this lot matches what the last project relied on.
This reliability doesn’t just rest on a single batch or vendor, either. Specifications stay consistent enough that switching suppliers rarely introduces surprises. Discussions with buyers and lab managers confirm these trends—they want reagents backed by clear paperwork, with COAs on file, with the assurance that storage, handling, and transportation haven’t undermined quality. This reagent ticks those boxes and avoids the pitfalls of “lowest-bidder” sourcing, which can tempt labs but backfire when research quality slips.
It’s one thing to run a handful of milligram-scale reactions in the academic lab. Scaling those up to pilot plant runs, or full commercial synthesis, brings a fresh set of hurdles. Compounds like 2-Acetamido-5-fluoropyridine, 97%, become pivotal for engineers and chemists bridging that gap. Consistent purity across kilos means fewer unexpected shutdowns or off-spec batches, which translates directly into lower costs and less interruption for the production schedule.
Drawing from experience supporting process development teams, small inconsistencies in reagent quality might be invisible at tiny scale but turn catastrophic as volume ramps up. Instead of absorbing extra filtration steps or quality checks, good starting material means a smoother ramp from research curiosity to market-ready product. This isn’t just a matter of dollars and cents; it also means finished products are safer, with well-documented origins that can answer tough regulatory questions down the line.
While the value of high-purity reagents is clear, challenges remain for researchers on tight budgets or with irregular access to specialty chemicals. Shipping restrictions, import rules, or bureaucratic snags can slow things down, especially for smaller labs. For wider adoption, supply chains need streamlining, with clearer compliance documentation and international availability. Those of us who have juggled global collaborations know that even the most reliable reagent serves little purpose if it can’t be shipped or cleared customs quickly.
There’s room for suppliers to cut down on red tape, improve transparency around sourcing, and broaden distribution channels. Shared purchasing cooperatives among research institutions offer one avenue; digital catalogues linked with real-time inventory represent another. In the end, the more efficiently these compounds move, the more possible it becomes for innovation to reach every bench and every application that needs it.
Safety standards continue to influence how laboratories source and use chemicals. 2-Acetamido-5-fluoropyridine requires handling protocols familiar to anyone working with organic nitrogen compounds and aromatic systems. Its relatively mild hazard profile, compared to more volatile fluorinated species, makes it approachable for well-equipped labs with standard fume hoods and protective equipment.
What matters most is that suppliers provide clear documentation on potential risks and best-practice handling. Training programs and onboarding sessions for new staff should reinforce these habits—label checking, minimum exposure, and waste management procedures. Having seen labs bounce back from near-misses, these routines make the difference between safe, productive research and disruptive accidents. Investing in compounds with reliable safety records pays off both in peace of mind and long-term laboratory efficiency.
Quality isn’t only about what goes on inside the flask. Supply chain transparency and ethical sourcing form an increasingly important part of responsible science. Laboratories looking to set themselves apart and stay ahead of compliance obligations benefit from working with suppliers who can tell a clear story about each product’s origin.
In larger organizations, procurement teams claim growing influence over how reagents are chosen, often tracking the chain of custody for starting materials. The goal isn’t just to shield the company from regulatory headaches—though that matters—but also to build confidence among research teams who want to know exactly what they’re working with. In this context, 2-Acetamido-5-fluoropyridine, 97%, stands as more than a bottle on the shelf; it’s a visible commitment to high standards and responsible practice.
Lab milestones come and go, but the ripple effects of using a reliable reagent can linger. A synthetic step that finishes in two hours instead of two days frees up time for deeper investigation and data analysis. Clean reactions make writing up results and preparing for publication less daunting, whether the audience is a thesis committee or an international patent office.
Colleagues often comment on the boost in morale that follows smoother workflows. Fewer supply chain surprises lower stress, lower overtime, and allow greater focus on creative problem-solving. In both early-stage research and late-stage development, this kind of compound acts as the anchor for larger, more ambitious goals. The “97%” label isn’t a marketing trick; it’s the foundation for building trust within project teams, between companies, and across continental divides.
Efforts to spread best practices rarely pick up steam unless enough researchers share their wins and failures. As one product in a larger push toward transparency and reliability, 2-Acetamido-5-fluoropyridine, 97%, can inspire labs to rethink old habits. By insisting on better documentation, batch records, and reproducibility, the whole field benefits—and the pace of discovery often increases as trial and error gives way to more informed risk-taking.
During roundtable discussions and mentorship sessions, these themes keep coming up. Stronger inputs build confidence, let teams take bigger swings, and help reputation keep pace with ambition. For every story of a breakthrough made possible by consistent chemistry, there’s another about setbacks caused by unreliable supplies. Those who make the switch to more rigorously sourced and tested reagents rarely look back.
Looking to the future, small changes in procurement, supply chain management, and transparency can unlock even greater returns. Cloud-based inventory tracking, vendor scorecards, and peer-to-peer reviews help separate trustworthy reagents from also-rans. Wider adoption of digital tools can flag consistency issues earlier, letting project managers adjust before trouble snowballs.
Industry cooperation and shared standards also matter. Organizations like the International Union of Pure and Applied Chemistry (IUPAC) and regional regulatory bodies continue to refine guidelines for purity, traceability, and labeling. The more widely these standards spread, the better equipped new researchers and veteran teams alike become to select high-performing materials and avoid unnecessary risk.
From every angle—scientific, operational, and regulatory—the decision to use a compound like 2-Acetamido-5-fluoropyridine, 97%, ripples outward. Whether the need is reliability in drug discovery, precision in material design, or simple peace of mind, this molecule earns its place as a solid choice for those determined to move science forward with clarity and confidence.
